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%global _empty_manifest_terminate_build 0
Name: python-pollination-pmv-comfort-map
Version: 0.8.16
Release: 1
Summary: PMV thermal comfort map for Pollination.
License: PolyForm Shield License 1.0.0, https://polyformproject.org/wp-content/uploads/2020/06/PolyForm-Shield-1.0.0.txt
URL: https://github.com/pollination/pmv-comfort-map
Source0: https://mirrors.aliyun.com/pypi/web/packages/cc/69/8193d1b1d2a39401366e3d6a6f35926f4a27674f5723fd52f4195cceb0b2/pollination-pmv-comfort-map-0.8.16.tar.gz
BuildArch: noarch
Requires: python3-pollination-ladybug
Requires: python3-pollination-ladybug-comfort
Requires: python3-pollination-honeybee-radiance
Requires: python3-pollination-honeybee-energy
Requires: python3-pollination-lbt-honeybee
Requires: python3-pollination-alias
Requires: python3-pollination-path
Requires: python3-pollination-honeybee-display
%description
# PMV Comfort Map
PMV thermal comfort map recipe for Pollination.
Compute spatially-resolved PMV thermal comfort from a Honeybee model and EPW.
This recipe also computes operative temperature or (optionally) Standard
Effective Temperature (SET). Raw results are written into a `results/` folder and
include CSV matrices of hourly temperatures, thermal conditions and PMV. Processed
metrics of Thermal Comfort Percent (TCP) can be found in the `metrics/` folder.
Input conditions to the comfort model are written to an `initial_results/conditions`
folder.
## Methods
This recipe uses EnergyPlus to obtain surface temperatures and indoor air
temperatures + humidities. Outdoor air temperatures, relative humidities, and
air speeds are taken directly from the EPW. All outdoor points are assumed to be
at one half of the EPW meteorological wind speed (effectively representing wind
speed at ground/human height).
Longwave radiant temperatures are achieved by computing spherical view factors
from each sensor to the surfaces of the model using Radiance. These view factors
are then multiplied by the surface temperatures output by EnergyPlus to yield
longwave MRT at each sensor. All indoor shades (eg. those representing furniture)
are assumed to be at the room-average MRT. For outdoor sensors, the EnergyPlus
outdoor surface temperatures are used and each sensor's sky view is multiplied by
the EPW sky temperature to account for longwave radiant exchange with the sky.
All outdoor context shades and the ground are assumed to be at the EPW air
temperature unless they have been modeled as Honeybee rooms.
A Radiance-based enhanced 2-phase method is used for all shortwave MRT calculations,
which precisely represents direct sun by tracing a ray from each sensor to the
solar position. The energy properties of the model geometry are what determine
the reflectance and transmittance of the Radiance materials in this shortwave
calculation.
To determine Thermal Comfort Percent (TCP), the occupancy schedules of the energy
model are used. Any hour of the occupancy schedule that is 0.1 or greater will be
considered occupied. For outdoor sensors, all hours are considered occupied.
%package -n python3-pollination-pmv-comfort-map
Summary: PMV thermal comfort map for Pollination.
Provides: python-pollination-pmv-comfort-map
BuildRequires: python3-devel
BuildRequires: python3-setuptools
BuildRequires: python3-pip
%description -n python3-pollination-pmv-comfort-map
# PMV Comfort Map
PMV thermal comfort map recipe for Pollination.
Compute spatially-resolved PMV thermal comfort from a Honeybee model and EPW.
This recipe also computes operative temperature or (optionally) Standard
Effective Temperature (SET). Raw results are written into a `results/` folder and
include CSV matrices of hourly temperatures, thermal conditions and PMV. Processed
metrics of Thermal Comfort Percent (TCP) can be found in the `metrics/` folder.
Input conditions to the comfort model are written to an `initial_results/conditions`
folder.
## Methods
This recipe uses EnergyPlus to obtain surface temperatures and indoor air
temperatures + humidities. Outdoor air temperatures, relative humidities, and
air speeds are taken directly from the EPW. All outdoor points are assumed to be
at one half of the EPW meteorological wind speed (effectively representing wind
speed at ground/human height).
Longwave radiant temperatures are achieved by computing spherical view factors
from each sensor to the surfaces of the model using Radiance. These view factors
are then multiplied by the surface temperatures output by EnergyPlus to yield
longwave MRT at each sensor. All indoor shades (eg. those representing furniture)
are assumed to be at the room-average MRT. For outdoor sensors, the EnergyPlus
outdoor surface temperatures are used and each sensor's sky view is multiplied by
the EPW sky temperature to account for longwave radiant exchange with the sky.
All outdoor context shades and the ground are assumed to be at the EPW air
temperature unless they have been modeled as Honeybee rooms.
A Radiance-based enhanced 2-phase method is used for all shortwave MRT calculations,
which precisely represents direct sun by tracing a ray from each sensor to the
solar position. The energy properties of the model geometry are what determine
the reflectance and transmittance of the Radiance materials in this shortwave
calculation.
To determine Thermal Comfort Percent (TCP), the occupancy schedules of the energy
model are used. Any hour of the occupancy schedule that is 0.1 or greater will be
considered occupied. For outdoor sensors, all hours are considered occupied.
%package help
Summary: Development documents and examples for pollination-pmv-comfort-map
Provides: python3-pollination-pmv-comfort-map-doc
%description help
# PMV Comfort Map
PMV thermal comfort map recipe for Pollination.
Compute spatially-resolved PMV thermal comfort from a Honeybee model and EPW.
This recipe also computes operative temperature or (optionally) Standard
Effective Temperature (SET). Raw results are written into a `results/` folder and
include CSV matrices of hourly temperatures, thermal conditions and PMV. Processed
metrics of Thermal Comfort Percent (TCP) can be found in the `metrics/` folder.
Input conditions to the comfort model are written to an `initial_results/conditions`
folder.
## Methods
This recipe uses EnergyPlus to obtain surface temperatures and indoor air
temperatures + humidities. Outdoor air temperatures, relative humidities, and
air speeds are taken directly from the EPW. All outdoor points are assumed to be
at one half of the EPW meteorological wind speed (effectively representing wind
speed at ground/human height).
Longwave radiant temperatures are achieved by computing spherical view factors
from each sensor to the surfaces of the model using Radiance. These view factors
are then multiplied by the surface temperatures output by EnergyPlus to yield
longwave MRT at each sensor. All indoor shades (eg. those representing furniture)
are assumed to be at the room-average MRT. For outdoor sensors, the EnergyPlus
outdoor surface temperatures are used and each sensor's sky view is multiplied by
the EPW sky temperature to account for longwave radiant exchange with the sky.
All outdoor context shades and the ground are assumed to be at the EPW air
temperature unless they have been modeled as Honeybee rooms.
A Radiance-based enhanced 2-phase method is used for all shortwave MRT calculations,
which precisely represents direct sun by tracing a ray from each sensor to the
solar position. The energy properties of the model geometry are what determine
the reflectance and transmittance of the Radiance materials in this shortwave
calculation.
To determine Thermal Comfort Percent (TCP), the occupancy schedules of the energy
model are used. Any hour of the occupancy schedule that is 0.1 or greater will be
considered occupied. For outdoor sensors, all hours are considered occupied.
%prep
%autosetup -n pollination-pmv-comfort-map-0.8.16
%build
%py3_build
%install
%py3_install
install -d -m755 %{buildroot}/%{_pkgdocdir}
if [ -d doc ]; then cp -arf doc %{buildroot}/%{_pkgdocdir}; fi
if [ -d docs ]; then cp -arf docs %{buildroot}/%{_pkgdocdir}; fi
if [ -d example ]; then cp -arf example %{buildroot}/%{_pkgdocdir}; fi
if [ -d examples ]; then cp -arf examples %{buildroot}/%{_pkgdocdir}; fi
pushd %{buildroot}
if [ -d usr/lib ]; then
find usr/lib -type f -printf "\"/%h/%f\"\n" >> filelist.lst
fi
if [ -d usr/lib64 ]; then
find usr/lib64 -type f -printf "\"/%h/%f\"\n" >> filelist.lst
fi
if [ -d usr/bin ]; then
find usr/bin -type f -printf "\"/%h/%f\"\n" >> filelist.lst
fi
if [ -d usr/sbin ]; then
find usr/sbin -type f -printf "\"/%h/%f\"\n" >> filelist.lst
fi
touch doclist.lst
if [ -d usr/share/man ]; then
find usr/share/man -type f -printf "\"/%h/%f.gz\"\n" >> doclist.lst
fi
popd
mv %{buildroot}/filelist.lst .
mv %{buildroot}/doclist.lst .
%files -n python3-pollination-pmv-comfort-map -f filelist.lst
%dir %{python3_sitelib}/*
%files help -f doclist.lst
%{_docdir}/*
%changelog
* Fri Jun 09 2023 Python_Bot <Python_Bot@openeuler.org> - 0.8.16-1
- Package Spec generated
|
